US2015071541A1
|
|
Automated method for measuring, classifying, and matching the dynamics and information passing of single objects within one or more images
|
WO2010019390A1
|
|
Converting nanoparticles in oil to aqueous suspensions
|
WO2009061972A1
|
|
Multimetallic nanoshells for monitoring chemical reactions
|
WO2009061477A1
|
|
Production of gamma-hydroxybutyrate
|
WO2008157812A1
|
|
Tungstated zirconia nanocatalysts
|
WO2008128234A1
|
|
Reduced phosphotransferase system activity in bacteria
|
WO2009002587A2
|
|
Synthesis of uniform nanoparticle shapes with high selectivity
|
WO2008147470A2
|
|
Anaerobic synthesis of oxidized products by e. coli
|
WO2008097353A2
|
|
Reduced activity of ubica in e. coli
|
WO2008028002A1
|
|
Increasing nadph-dependent products
|
CN101415830A
|
|
Anaerobic fermentation of glycerol
|
US2006141594A1
|
|
Simultaneous anaerobic production of isoamyl acetate and succinic acid
|
CN101023178A
|
|
High succinate producing bacteria
|
CN101044245A
|
|
Mutant e. coli strain with increased succinic acid production
|
US2006040368A1
|
|
Aerobic succinate production in bacteria
|
US2007020740A1
|
|
Blocking sporulation by inhibiting SpoIIE
|
US2005170482A1
|
|
Aerobic succinate production in bacteria
|
US2005196866A1
|
|
Increasing intracellular NADPH availability in E. coli
|
US7927859B2
|
|
High molar succinate yield bacteria by increasing the intracellular NADH availability
|
US2005054571A1
|
|
Antimicrobial proteins from the SPO1 bacteriophage
|